It turns out that in practice another solution worked out (in fact, the mix of the engineer’s and mythbuster’s solutions). You can ruin the city during a world war and then transfer it to Russians, who will build the new bridges instead. I’ve been to Kaliningrad (the city has been renamed too) two years ago, but did not try to solve the Euler’s problem in field. Let’s find out if it is possible now. Look at the modern map:

So, the modified Spiked Math’s scheme looks as follows (the new bridges are shown in light blue):

Is there an Eulerian path nowadays, i.e. can you walk through the city and cross each bridge once and only once? Recall the theorem:

A connected graph allows an Eulerian path if and only if it has no more than two vertices of an odd degree.

In the picture above, two pieces of land have even number of incident bridges, while the Kneiphof island in the center has degree 3, and the left bank (in the bottom) has degree 5. This means that now Eulerian paths exist. Any such path should begin in the left bank and end in the island, or vice-versa. It may be a good idea to finish your journey near the grave of Immanuel Kant. :) However, there is no Eulerian conduit, i.e. closed Eulerian path.

PS. 1. If you zoom out the above map, you’ll see one more piece of land and two more bridges on the East. However, it only adds a vertex of degree 2, and swaps parity of the banks, so the properties of the new graph are similar, you just need to start/finish your journey in the right bank, not the left one (and walk 10 km more).

2. When I was preparing this article, I found a similar analysis. It used an old map, so the Jubilee bridge and the 2nd Estacade bridges were not marked (they were built in 2005 and 2012, respectively), and also ignored the Reichsbahnbrüke (railroad bridge, but seems pedestrian-accessible).

3. It would be more interesting to analyze the bridge graphs of other cities with more islands like St. Petersburg (several hundred bridges) or Amsterdam (numerous bridges/canals, but have structure).4. Here is Euler’s original paper (in Latin) with his drawings of the above schemes.